Abstract

To fulfill the roles the lymphatic system plays in body fluid regulation, macromolecular homeostasis, lipid absorption, immune function, it must transport lymph from the interstitium, along the lymphatic network, through the nodes, into the great veins of the neck. Lymphatic muscle utilizes a unique combination of tonic and phasic contractions and muscle contractile proteins to generate and control lymph flow/transport. Contraction of lymphatic muscle is driven and regulated by both physical and ionic events. Stretch of the lymphatic wall is the most well documented physical stimulator of lymphatic function. Lymphatic muscle ionic events drive the electrical activity and intracellular calcium to modulate contraction. However, the ionic mechanisms regulating lymphatic muscle contraction and how stretch activates them are relatively unknown. To gain a better understanding of the regulation of lymphatic function, we propose to investigate the ionic mechanisms of lymphatic muscle contraction and how they are affected by stretch in isolated rat mesenteric lymphatics. Dysfunctional lymphatics result in a wide range of clinical problems. This project will substantially advance our understanding of lymphatic biology and provide the basis for the eventual development of therapeutic strategies to diagnose and treat lymphatic contractile dysfunction.

Public Health Relevance

To fulfill the roles the lymphatic system plays in body fluid and macromolecular regulation, lipid absorption and immune function, it transports lymph from the interstitium, along the lymphatic network, through the nodes, into the great veins of the neck using contractions of the lymphatic muscle to generate and control lymph flow. However, the ionic mechanisms regulating lymphatic muscle contraction and how stretch (the predominant physical factor that regulate lymph pumping) activates them are unknown. This project will substantially advance our understanding of lymphatic biology and provide the basis for the development of therapeutic strategies to treat lymphatic contractile dysfunction, which can result in a wide range of clinical problems.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
1R01HL096552-01
Application #
7691633
Study Section
Special Emphasis Panel (ZRG1-CVS-P (50))
Program Officer
Goldman, Stephen
Project Start
2009-09-01
Project End
2013-07-31
Budget Start
2009-09-01
Budget End
2010-07-31
Support Year
1
Fiscal Year
2009
Total Cost
$458,768
Indirect Cost

  Institution

Name
Texas A&M University
Department
Physiology
Type
Schools of Medicine
DUNS #
835607441
City
College Station
State
TX
Country
United States
Zip Code
77845

  Publications

Chen, Yingxuan; Rehal, Sonia; Roizes, Simon et al. (2017) The pro-inflammatory cytokine TNF-? inhibits lymphatic pumping via activation of the NF-?B-iNOS signaling pathway. Microcirculation 24:
Jamalian, Samira; Jafarnejad, Mohammad; Zawieja, Scott D et al. (2017) Demonstration and Analysis of the Suction Effect for Pumping Lymph from Tissue Beds at Subatmospheric Pressure. Sci Rep 7:12080
Rehal, Sonia; von der Weid, Pierre-Yves (2017) TNF?ARE Mice Display Abnormal Lymphatics and Develop Tertiary Lymphoid Organs in the Mesentery. Am J Pathol 187:798-807
Chakraborty, Sanjukta; Zawieja, David C; Davis, Michael J et al. (2015) MicroRNA signature of inflamed lymphatic endothelium and role of miR-9 in lymphangiogenesis and inflammation. Am J Physiol Cell Physiol 309:C680-92
Wilson, John T; van Loon, Raoul; Wang, Wei et al. (2015) Determining the combined effect of the lymphatic valve leaflets and sinus on resistance to forward flow. J Biomech 48:3584-90
Kuan, Emma L; Ivanov, Stoyan; Bridenbaugh, Eric A et al. (2015) Collecting lymphatic vessel permeability facilitates adipose tissue inflammation and distribution of antigen to lymph node-homing adipose tissue dendritic cells. J Immunol 194:5200-10
Al-Kofahi, M; Becker, F; Gavins, F N E et al. (2015) IL-1? reduces tonic contraction of mesenteric lymphatic muscle cells, with the involvement of cycloxygenase-2 and prostaglandin E2. Br J Pharmacol 172:4038-51
Jafarnejad, M; Cromer, W E; Kaunas, R R et al. (2015) Measurement of shear stress-mediated intracellular calcium dynamics in human dermal lymphatic endothelial cells. Am J Physiol Heart Circ Physiol 308:H697-706
Jafarnejad, Mohammad; Woodruff, Matthew C; Zawieja, David C et al. (2015) Modeling Lymph Flow and Fluid Exchange with Blood Vessels in Lymph Nodes. Lymphat Res Biol 13:234-47
Zolla, Valerio; Nizamutdinova, Irina Tsoy; Scharf, Brian et al. (2015) Aging-related anatomical and biochemical changes in lymphatic collectors impair lymph transport, fluid homeostasis, and pathogen clearance. Aging Cell 14:582-94

Showing the most recent 10 out of 31 publications